TY - GEN
T1 - Approximate Robust Tube Nonlinear Model Predictive Control for Vehicle Collision Avoidance
AU - Kim, Seungtaek
AU - Han, Kyoungseok
AU - Choi, Seibum B.
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - The key to vehicle collision avoidance is achieving optimal avoidance performance with a reasonable computational load for real-time applications. To address these requirements, this study applies a novel approach by designing a robust tube nonlinear model predictive controller (RTNMPC) and approximating it to a neural network, thereby ensuring both optimal collision avoidance performance and realtime capability. The RTNMPC optimally controls the vehicle's steering and differential braking forces to guide it to a safe lane, minimizing the avoidance trajectory area. Tightened tire grip constraints were applied to robustly maintain vehicle maneuverability under system uncertainties and approximation errors in the neural network controller. Grip constraints were further relaxed by introducing a practical constraint tightening approach with an input saturation process based on tire grip usage. Consequently, the proposed collision avoidance system achieved both greater collision avoidance results with the lowest computational load compared to the baselines in CarSim simulations.
AB - The key to vehicle collision avoidance is achieving optimal avoidance performance with a reasonable computational load for real-time applications. To address these requirements, this study applies a novel approach by designing a robust tube nonlinear model predictive controller (RTNMPC) and approximating it to a neural network, thereby ensuring both optimal collision avoidance performance and realtime capability. The RTNMPC optimally controls the vehicle's steering and differential braking forces to guide it to a safe lane, minimizing the avoidance trajectory area. Tightened tire grip constraints were applied to robustly maintain vehicle maneuverability under system uncertainties and approximation errors in the neural network controller. Grip constraints were further relaxed by introducing a practical constraint tightening approach with an input saturation process based on tire grip usage. Consequently, the proposed collision avoidance system achieved both greater collision avoidance results with the lowest computational load compared to the baselines in CarSim simulations.
UR - https://www.scopus.com/pages/publications/105017854355
U2 - 10.1109/CCTA53793.2025.11151526
DO - 10.1109/CCTA53793.2025.11151526
M3 - Conference contribution
AN - SCOPUS:105017854355
T3 - 2025 IEEE Conference on Control Technology and Applications, CCTA 2025
SP - 33
EP - 38
BT - 2025 IEEE Conference on Control Technology and Applications, CCTA 2025
A2 - Vermillion, Christopher
A2 - Olaru, Sorin
A2 - Mathieu, Johanna
A2 - Mercangoz, Mehmet
A2 - Stockar, Stephanie
A2 - Karimi, Alireza
A2 - Faulwasser, Timm
A2 - Kerrigan, Eric
A2 - Fineisen, Rolf
A2 - Gros, Sebastien
A2 - Prodan, Ionela
A2 - Edwards, Christopher
A2 - Dabbene, Fabrizio
A2 - Chapman, Airlie
A2 - Touri, Behrouz
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 9th IEEE Conference on Control Technology and Applications, CCTA 2025
Y2 - 25 August 2025 through 27 August 2025
ER -